I assume, *scalaz 7.0.x* and the following imports (look at answer history for *scalaz 6.x*):

```
import scalaz._
import Scalaz._
```

The state type is defined as `State[S, A]`

where `S`

is type of the state and `A`

is the type of the value being decorated. The basic syntax to create a state value makes use of the `State[S, A]`

function:

```
// Create a state computation incrementing the state and returning the "str" value
val s = State[Int, String](i => (i + 1, "str"))
```

To run the state computation on a initial value:

```
// start with state of 1, pass it to s
s.eval(1)
// returns result value "str"
// same but only retrieve the state
s.exec(1)
// 2
// get both state and value
s(1) // or s.run(1)
// (2, "str")
```

The state can be threaded through function calls. To do this instead of `Function[A, B]`

, define `Function[A, State[S, B]]]`

. Use the `State`

function...

```
import java.util.Random
def dice() = State[Random, Int](r => (r, r.nextInt(6) + 1))
```

Then the `for/yield`

syntax can be used to compose functions:

```
def TwoDice() = for {
r1 <- dice()
r2 <- dice()
} yield (r1, r2)
// start with a known seed
TwoDice().eval(new Random(1L))
// resulting value is (Int, Int) = (4,5)
```

Here is another example. Fill a list with `TwoDice()`

state computations.

```
val list = List.fill(10)(TwoDice())
// List[scalaz.IndexedStateT[scalaz.Id.Id,Random,Random,(Int, Int)]]
```

Use sequence to get a `State[Random, List[(Int,Int)]]`

. We can provide a type alias.

```
type StateRandom[x] = State[Random,x]
val list2 = list.sequence[StateRandom, (Int,Int)]
// list2: StateRandom[List[(Int, Int)]] = ...
// run this computation starting with state new Random(1L)
val tenDoubleThrows2 = list2.eval(new Random(1L))
// tenDoubleThrows2 : scalaz.Id.Id[List[(Int, Int)]] =
// List((4,5), (2,4), (3,5), (3,5), (5,5), (2,2), (2,4), (1,5), (3,1), (1,6))
```

Or we can use `sequenceU`

which will infer the types:

```
val list3 = list.sequenceU
val tenDoubleThrows3 = list3.eval(new Random(1L))
// tenDoubleThrows3 : scalaz.Id.Id[List[(Int, Int)]] =
// List((4,5), (2,4), (3,5), (3,5), (5,5), (2,2), (2,4), (1,5), (3,1), (1,6))
```

Another example with `State[Map[Int, Int], Int]`

to compute frequency of sums on the list above. `freqSum`

computes the sum of the throws and counts frequencies.

```
def freqSum(dice: (Int, Int)) = State[Map[Int,Int], Int]{ freq =>
val s = dice._1 + dice._2
val tuple = s -> (freq.getOrElse(s, 0) + 1)
(freq + tuple, s)
}
```

Now use traverse to apply `freqSum`

over `tenDoubleThrows`

. `traverse`

is equivalent to `map(freqSum).sequence`

.

```
type StateFreq[x] = State[Map[Int,Int],x]
// only get the state
tenDoubleThrows2.copoint.traverse[StateFreq, Int](freqSum).exec(Map[Int,Int]())
// Map(10 -> 1, 6 -> 3, 9 -> 1, 7 -> 1, 8 -> 2, 4 -> 2) : scalaz.Id.Id[Map[Int,Int]]
```

Or more succinctly by using `traverseU`

to infer the types:

```
tenDoubleThrows2.copoint.traverseU(freqSum).exec(Map[Int,Int]())
// Map(10 -> 1, 6 -> 3, 9 -> 1, 7 -> 1, 8 -> 2, 4 -> 2) : scalaz.Id.Id[Map[Int,Int]]
```

Note that because `State[S, A]`

is a type alias for `StateT[Id, S, A]`

, tenDoubleThrows2 ends up being typed as `Id`

. I use `copoint`

to turn it back into a `List`

type.

In short, it seems the key to use state is to have functions returning a function modifying the state and the actual result value desired... *Disclaimer: I have never used *`state`

in production code, just trying to get a feel for it.

**Additional info on @ziggystar comment**

I gave up on trying using `stateT`

may be someone else can show if `StateFreq`

or `StateRandom`

can be augmented to perform the combined computation. What I found instead is that the composition of the two state transformers can be combined like this:

```
def stateBicompose[S, T, A, B](
f: State[S, A],
g: (A) => State[T, B]) = State[(S,T), B]{ case (s, t) =>
val (newS, a) = f(s)
val (newT, b) = g(a) apply t
(newS, newT) -> b
}
```

It's predicated on `g`

being a one parameter function taking the result of the first state transformer and returning a state transformer. Then the following would work:

```
def diceAndFreqSum = stateBicompose(TwoDice, freqSum)
type St2[x] = State[(Random, Map[Int,Int]), x]
List.fill(10)(diceAndFreqSum).sequence[St2, Int].exec((new Random(1L), Map[Int,Int]()))
```